A decision-based perspective for the design of methods for systems design

Organization of material, a definition of decision based design, a hierarchy of decision based design, the decision support problem technique, a conceptual model design that can be manufactured and maintained, meta-design, computer-based design, action learning, and the characteristics of decisions are among the topics covered

ChainMail: A configurable multimodal lining to enable sensate surfaces and interactive objects

The ChainMail system is a scalable electronic sensate skin that is designed as a dense sensor network. ChainMail is built from small (1"x1") rigid circuit boards attached to their neighbors with flexible interconnects that allow the skin to be conformally arranged and manipulated. Each board contains an embedded processor together with a suite of thirteen sensors, providing dense, multimodal capture of proximate and contact phenomena. This system forms a sensate lining that can be applied to an object, device, or surface to enable interactivity. Under extended testing, we demonstrate a flexible skin to detect and respond to a variety of stimuli while running quickly and efficiently.National Science Foundation (U.S.) (Graduate Research Fellowship number 2007050798

The design of aircraft using the decision support problem technique

The Decision Support Problem Technique for unified design, manufacturing and maintenance is being developed at the Systems Design Laboratory at the University of Houston. This involves the development of a domain-independent method (and the associated software) that can be used to process domain-dependent information and thereby provide support for human judgment. In a computer assisted environment, this support is provided in the form of optimal solutions to Decision Support Problems

Using System Dynamics to Model and Better Understand State Stability

The world can be complex and dangerous - the loss of state stability of countries is of increasing concern. Although every case is unique, there are important common processes. We have developed a system dynamics model of state stability based on an extensive review of the literature and debriefings of subject matter experts. We represent the nature and dynamics of the ‘loads’ generated by insurgency activities, on the one hand, and the core features of state resilience and its ‘capacity’ to withstand these ‘loads’, on the other. The challenge is to determine when threats to stability override the resilience of the state and, more important, to anticipate conditions under which small additional changes in anti-regime activity can generate major disruptions. With these insights, we can identify appropriate and actionable mitigation factors to decrease the likelihood of radical shifts in behavior and enhance prospects for stability

The House of Security: Stakeholder Perceptions of Security Assessment and Importance

In this paper we introduce a methodology for analyzing differences regarding security perceptions within and between stakeholders, and the elements which affect these perceptions. We have designed the “House of Security”, a security assessment model that provides the basic framework for considering eight different constructs of security: Vulnerability, Accessibility, Confidentiality, Technology Resources for Security, Financial Resources for Security, Business Strategy for Security, Security Policy and Procedures, and Security Culture. We designed and performed a survey of about 1500 professionals in various industries, levels, and functions resulting in a gap analysis to uncover differences (1) between the different constructs and aspects of security, (2) between different enterprise stakeholder roles, and (3) between different organizations. This paper briefly describes the development of the security constructs and some of the preliminary findings

Measuring Stakeholders’ Perceptions of Cybersecurity for Renewable Energy Systems

Renewable energy systems need to be able to make frequent and rapid adjustments to address shifting solar and wind production. This requires increasingly sophisticated industrial control systems (ICS). But, that also increases the potential risks from cyber-attacks. Despite increasing attention to technical aspects (i.e., software and hardware) of cybersecurity, many professionals and scholars pay little or no attention to its organizational aspects, particularly to stakeholders’ perceptions of the status of cybersecurity within organizations. Given that cybersecurity decisions and policies are mainly made based on stakeholders’ perceived needs and security views, it is critical to measure such perceptions. In this paper, we introduce a methodology for analyzing differences in perceptions of cybersecurity among organizational stakeholders. To measure these perceptions, we first designed House of Security (HoS) as a framework that includes eight constructs of security: confidentiality, integrity, availability, technology resources, financial resources, business strategy, policy and procedures, and culture. We then developed a survey instrument to analyze stakeholders’ perceptions based on these eight constructs. In a pilot study, we used the survey with people in various functional areas and levels of management in two energy and ICS organizations, and conducted a gap analysis to uncover differences in cybersecurity perceptions. This paper introduces the HoS and describes the survey instrument, as well as some of the preliminary findings. Keywords: Smart Grid; Functional Area; Operational Technology; Organizational Aspect; Renewable Energy Resourc

Understanding & Modeling State Stability: Exploiting System Dynamics

The potential loss of state stability in various parts of the world is a source of threat to U.S. national security. Every case is unique, but there are common processes. Accordingly, we develop a system dynamics model of state stability by representing the nature and dynamics of ‘loads’ generated by insurgency activities, on the one hand, and by articulating the core features of state resilience and its ‘capacity’ to withstand these ‘loads’, on the other. The problem is to determine and ‘predict’ when threats to stability override the resilience of the state and, more important, to anticipate propensities for ‘tipping points’, namely conditions under which small changes in anti-regime activity can generate major disruptions. On this basis, we then identify appropriate actionable mitigation factors to decrease the likelihood of ‘tipping’ and enhance prospects for stability

A flexible high-density sensor network

Thesis (M. Eng.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2008.Includes bibliographical references (p. 171-174).This thesis explores building and deploying a scalable electronic sensate skin that was designed as a dense sensor network. Our skin is built from small (1" x 1") rigid circuit boards attached to their neighbors with flexible interconnects. Each boardcontained an embedded processor together with a suite of thirteen sensors, providing dense, multimodal capture of proximate and contact phenomena. In addition to the design of the physical system, this thesis develops protocols for internode communication (both neighbor-neighbor and global), and power-efficient wake-on-phenomena operation. The system was rigorously tested with an array of up to 4x3 nodes subject to a variety of sensor stimuli. Although there were some robustness issues in the final design (particularly in the wired interconnects, which were not the focus of this thesis work), the skin that we developed showed good flexibility for a prototype, ran quickly and efficiently, and could detect and respond to a variety of stimuli.by Behram Farrokh Thomas Mistree.M.Eng

Simulation reduction using the Taguchi method

A large amount of engineering effort is consumed in conducting experiments to obtain information needed for making design decisions. Efficiency in generating such information is the key to meeting market windows, keeping development and manufacturing costs low, and having high-quality products. The principal focus of this project is to develop and implement applications of Taguchi's quality engineering techniques. In particular, we show how these techniques are applied to reduce the number of experiments for trajectory simulation of the LifeSat space vehicle. Orthogonal arrays are used to study many parameters simultaneously with a minimum of time and resources. Taguchi's signal to noise ratio is being employed to measure quality. A compromise Decision Support Problem and Robust Design are applied to demonstrate how quality is designed into a product in the early stages of designing